A method for controlling the rate of aluminum fluoride addition to a cryolite-based electrolyte of an aluminum electrolytic reduction cell makes use of the known ratio between cell temperature and bath (NaF:alf3) ratio. A target temperature is established corresponding to a target bath ratio. The cell temperature is measured at intervals and the rate of alf3 addition altered depending on whether the measured temperature is above or below the target temperature. The method is faster than traditional methods involving analysis of electrolyte samples, and is amendable to computer control.

Patent
   4668350
Priority
Mar 18 1985
Filed
Mar 17 1986
Issued
May 26 1987
Expiry
Mar 17 2006
Assg.orig
Entity
Large
7
2
EXPIRED
1. A method of controlling the addition of alf3 to a cryolite-based electrolyte of an aluminium electrolytic reduction cell, which method comprises:
(a) establishing a target cell temperature (Tt),
(b) establishing a standard rate of addition of alf3,
(c) measuring the actual cell temperature (T),
(d) in response to the actual temperature measurement (c) altering the rate of addition of alf3, increasing the rate if T is greater than Tt, and decreasing the rate if T is less than Tt, and
(e) repeating steps (c) and (d) at intervals.
2. A method of controlling the addition of alf3 to a cryolite-based electrolyte of an aluminium electrolytic reduction cell, which method comprises the following steps:
(a) Establishing a target operating temperature for the cell, which depends on the target bath ratio,
(b) Establishing a standard alf3 addition rate which corresponds with the needs of a cell running in a stable condition at the target temperature,
(c) Measuring the actual cell temperature on a regular basis,
(d) Determining a first correction based on the difference between the actual measured temperature and the target temperature,
(e) Determining a second correction based on the difference between the actual measured temperature and the preceding measured temperature,
(f) Applying the first and second corrections to the standard alf3 addition rate to define a corrected alf3 addition rate,
(g) Making alf3 additions to the electrolyte at that corrected rate within a given period of time after making the temperature measurement.
3. A method as claimed in claim 2, wherein step f is performed by means of the following formula:
An+1 =K1 (Tt -Tn)+K2 8Tn -Tn-1)+As
where
An+1 is the corrected alf3 addition to be made during period n+1,
As is the standard alf3 addition corresponding to the needs of the cell when stable at the target temperature,
Tt is target electrolyte temperature of the operating cell,
Tn is actual measured electrolyte temperature at the point of time n,
Tn-1 is the actual temperature obtained by the preceding measurement at commencement of period n-1,
K1 is a constant which is applied to the difference between Tt and Tn to obtain a first required correction,
K2 is a constant which is applied to the difference between Tn and Tn-1 to obtain a second required correction.
4. A method as claimed in claim 3, wherein K1 and K2 are established by statistical analysis of the relationship between change in electrolyte temperature and alf3 requirements.
5. A method as claimed in claim 2, wherein control of the cell is performed by a computer.
6. A method as claimed in claim 1, wherein control of the cell is performed by a computer.

The process of Hall and Heroult for the production of aluminium by the electrolytic reduction of alumina (Al2 O3) involves the use of an electrolyte based on molten cryolite (Na3 AlF6). The electrolyte contains an addition of 5 to 7% of aluminium fluoride (AlF3), which lowers the melting point so as to permit operation in the range 950° to 1000°C, and lowers the content of reduced species in the electrolyte and thereby improves current efficiency. Losses of AlF3 during operation of the cell are made good by addition of fresh AlF3 to the electrolyte; for example, the AlF3 requirement for a 275 KA cell may be around 60 Kg per day. Generally, a target ratio of NaF:AlF3 is established for a cell, which may be for example around 1.10 by weight, and AlF3 additions adjusted with reference to this ratio.

In conventional operation, samples of electrolyte are periodically withdrawn and analysed for bath ratio by determination of their chemical composition. The AlF3 requirements of the electrolyte are deduced from the bias between the actual value of the bath ratio and the target value. This method has the disadvantage of requiring time for sampling and analysis (even though modern techniques such as X-ray diffraction may be used). Sample identities need to be carefully preserved to avoid mistakes. It is an object of the present invention to provide a method of controlling AlF3 additions to the electrolyte, which is simpler and quicker and is amenable to computerized operation.

It is well known that, under steady state operation of a cell, there is a relationship between bath ratio and electrolyte temperature, which is substantially linear within the normal operating range specifically, as the bath ratio rises, (e.g. as a result of removal of AlF3 from the system) the electrolyte temperature also rises. This relationship holds good over a range of about 10°C greater or less than the target operating temperature of the cell, and it is with this fairly narrow range that the present invention is concerned. It may be noted that there are inevitably fluctuations of electrolyte temperature arising, for example, from changes in the anode-cathode distance or the Al2 O3 concentration, but these are essentially short-term changes, continuing for minutes or at most a few hours. Since changes in bath ratio are measured over periods of at least several hours, these short-term changes can generally be ignored.

This invention makes use of the known dependence of electrolyte temperature on bath ratio to control the rate of addition of AlF3 to the electrolyte. Thus in a broad sense, the invention provides a method of controlling the addition of AlF3 to a cryolite-based electrolyte of an aluminium electrolytic reduction cell, which method comprises:

(a) establishing a target cell temperature (Tt),

(b) establishing a standard rate of addition of AlF3,

(c) measuring the actual cell temperature (T),

(d) in response to the actual temperature measurement (c) altering the rate of addition of AlF3, increasing the rate if T is greater than Tt, and decreasing the rate if T is less than Tt, and

(e) repeating steps (c) and (d) at intervals.

Establishing a target cell temperature is tantamount to establishing a target bath ratio, and can be done by conventional means. If desired, the method of this invention can be enlarged to alter the target cell temperature from time to time in the light of changing conditions. However, it is usually found that the target cell temperature remains constant during the life of the cell.

To establish a standard rate of addition of AlF3, it is merely necessary to determine approximately the average AlF3 requirements of the cell over a period of time. This standard rate may change with time.

Cell temperature may be measured in a variety of ways and at a variety of locations. It is possible to measure the electrolyte temperature directly; but, as noted above, this may not always be satisfactory due to short-term fluctuations in electrolyte temperature. Alternatively, cell temperature can be measured by means inserted in the side wall, or the floor, or in a cathode current collector in the cell floor. In cells with conventional carbon floors, horizontal steel bars are used to recover the current, and thermocouples can conveniently be positioned at intervals along a longitudinal hole in one of these. Temperature measurements effected within the wall or floor of the cell have the advantage that they should not be affected by short term fluctuations.

AlF3 additions are generally made in batches at suitable intervals of time. Altering the rate of addition of AlF3 may involve altering the size of the batches or the intervals between additions, or both. For example, the rate of AlF3 addition may be doubled if the actual temperature is above the target temperature, or halved if the actual temperature is below the target temperature. This altered rate of addition may be continued for a specified time or until the next temperature measurement is effected. It should not be necessary to measure the actual cell temperature more than once every few hours, and indeed a measurement once every twenty-four hours generally provides a perfectly satisfactory level of control.

A preferred embodiment of the method of the invention comprises the following steps:

1. Establishing a target operating temperataure for the cell, which depends on the target bath ratio.

2. Establishing a standard AlF3 addition rate which corresponds with the needs of a cell running in a stable condition at the target temperature.

3. Measuring the actual cell temperature on a regular basis, e.g. every twenty-four hours.

4. Determining a first correction based on the difference between the actual measured temperature and the target temperature.

5. Determining a second correction based on the difference between the actual measured temperature and the preceding measured temperature.

6. Applying the first and second corrections to the standard AlF3 addition rate to define a corrected AlF3 addition rate.

7. Making AlF3 additions to the electrolyte at that corrected rate within a given period of time after making the temperature measurement.

The method of the invention can easily be applied to computer control of cell operation by applying the following formula:

An+1 ×K1 (Tt -Tn)+K2 (Tn -Tn-1)+As

Where

An+1 is the corrected AlF3 addition to be made during period n+1.

As is the standard AlF3 addition corresponding to the needs of the cell when stable at the target temperature.

Tt is target electrolyte temperature of the operating cell.

Tn is actual measured electrolyte temperature at the point of time n.

Tn-1 is the actual temperature obtained by the preceding measurement at commencement of period n-1.

K1 is a constant which is applied to the difference between Tt and Tn to obtain a first required correction.

K2 is a constant which is applied to the difference between Tn and Tn-1 to obtain a second required correction.

K1 and K2 are functions of cell size and amperage and desired speed of response. They may be a established by a statistical analysis of the relationship between change in electrolyte temperature and AlF3 requirements. However, if K1 and K2 are chosen such that the speed of response is too rapid, then there is a danger of overcontrol. K, should generally be larger than, and opposite in sign to, K2. In practice, the value of K, is found to vary in approximate linear relationship with the volume of molten cell electrolyte.

In a 275 KA cell, the following values were determined by experiment.

Tt =955°C, this corresponding to a desired bath ratio of 1.10.

As =60 Kg/24h.

K1 =-5 Kg/°C. day.

K2 =2 Kg/°C. day.

During an eleven day period the cell electrolyte was sampled for bath ratio determination once every 24h., electrolyte temperature being measured at the time of sampling. The following table shows the AlF3 additions required according to the above mentioned formula.

______________________________________
Electrolyte Bath AlF3 Addition
Temperature °C.
Ratio Kg/24 h.
______________________________________
947 1.09 28
949 1.04 34
949 1.10 30
948 1.07 23
952 1.10 53
951 1.05 38
952 1.11 47
960 1.06 101
947 1.07 nil*
948 1.09 27
947 1.05 18
______________________________________
*Formula gave negative value

At no time during this period did the bath ratio deviate from the target by more than 0.05.

Huni, Jean-Paul R., Desclaux, Paul

Patent Priority Assignee Title
5094728, May 04 1990 Alusuisse-Lonza Services Ltd. Regulation and stabilization of the AlF3 content in an aluminum electrolysis cell
6183620, Feb 12 1998 HERAEUS ELECTRO-NITE INTERNATINAL N V Process for controlling the A1F3 content in cryolite melts
7112269, Aug 21 2003 Alcoa Inc Measuring duct offgas temperatures to improve electrolytic cell energy efficiency
7135104, Feb 28 2001 Aluminum Pechiney Method for regulating an electrolysis cell
7255783, Aug 21 2003 ALCOA USA CORP Use of infrared imaging to reduce energy consumption and fluoride consumption
7378009, May 05 2004 Russian Engineering Company, LLC Method of controlling an aluminum cell with variable alumina dissolution rate
7731824, Aug 21 2003 Alcoa Inc Measuring duct offgas temperatures to improve electrolytic cell energy efficiency
Patent Priority Assignee Title
4045308, Nov 04 1976 Aluminum Company of America Bath level set point control in an electrolytic cell and method of operating same
4377452, Jun 06 1980 Aluminium de Grece Process and apparatus for controlling the supply of alumina to a cell for the production of aluminum by electrolysis
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Executed onAssignorAssigneeConveyanceFrameReelDoc
Mar 10 1986DESCLAUX, PAULAlcan International LimitedASSIGNMENT OF ASSIGNORS INTEREST 0045280733 pdf
Mar 10 1986HUNI, JEAN-PAUL R Alcan International LimitedASSIGNMENT OF ASSIGNORS INTEREST 0045280733 pdf
Mar 17 1986Alcan International Limited(assignment on the face of the patent)
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